EP3274750B1 - Ofdr interferometric alignment of optical multicore fibers to be connected, and ofdr multicore fiber distributed strain sensor - Google Patents
Ofdr interferometric alignment of optical multicore fibers to be connected, and ofdr multicore fiber distributed strain sensor Download PDFInfo
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- EP3274750B1 EP3274750B1 EP16773799.8A EP16773799A EP3274750B1 EP 3274750 B1 EP3274750 B1 EP 3274750B1 EP 16773799 A EP16773799 A EP 16773799A EP 3274750 B1 EP3274750 B1 EP 3274750B1
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- G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
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- G02B6/38—Mechanical coupling means having fibre to fibre mating means
- G02B6/3807—Dismountable connectors, i.e. comprising plugs
- G02B6/3873—Connectors using guide surfaces for aligning ferrule ends, e.g. tubes, sleeves, V-grooves, rods, pins, balls
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- G02B6/3834—Means for centering or aligning the light guide within the ferrule
- G02B6/3843—Means for centering or aligning the light guide within the ferrule with auxiliary facilities for movably aligning or adjusting the fibre within its ferrule, e.g. measuring position or eccentricity
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- G01B—MEASURING LENGTH, THICKNESS OR SIMILAR LINEAR DIMENSIONS; MEASURING ANGLES; MEASURING AREAS; MEASURING IRREGULARITIES OF SURFACES OR CONTOURS
- G01B11/00—Measuring arrangements characterised by the use of optical techniques
- G01B11/26—Measuring arrangements characterised by the use of optical techniques for measuring angles or tapers; for testing the alignment of axes
- G01B11/27—Measuring arrangements characterised by the use of optical techniques for measuring angles or tapers; for testing the alignment of axes for testing the alignment of axes
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- G01M11/00—Testing of optical apparatus; Testing structures by optical methods not otherwise provided for
- G01M11/30—Testing of optical devices, constituted by fibre optics or optical waveguides
- G01M11/31—Testing of optical devices, constituted by fibre optics or optical waveguides with a light emitter and a light receiver being disposed at the same side of a fibre or waveguide end-face, e.g. reflectometers
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Definitions
- the technology relates to using an optical frequency domain reflectometer system for aligning a sensing multicore optical fiber with an interrogating multicore optical fiber, and carrying out distributed strain sensing.
- Optical fibers contain one or more optical cores surrounded typically by cladding, a buffer material, and a jacket. Optical fibers need to be connected accurately, reliably, and inexpensively. This is challenging for optical fibers that contain multiple optical cores, referred to as a "multicore fiber," because each of the corresponding cores should be aligned when two multicore fibers are connected. Even when the outer surfaces of the two multicore fibers, e.g., the ferrules covering the fibers, are aligned in a connector, the corresponding cores within the connector for the two fibers may not be aligned or could be aligned more accurately. Small misalignments can adversely impact the amount of light transferred between the connected multicore fibers.
- US 2012/0069347 A1 discloses an interferometric measurement system which includes a spun optical fiber including multiple optical waveguides configured in the fiber.
- Interferometric detection circuitry detects measurement interferometric pattern data associated with each of the multiple optical waveguides when the optical fiber is placed into a bend.
- Data processing circuitry determines compensation parameters that compensate for variations between an optimal configuration of the multiple optical waveguides in the fiber and an actual configuration of multiple optical waveguides in the fiber.
- the compensation parameters are stored in memory for compensating subsequently-obtained measurement interferometric pattern data for the fiber.
- the compensation parameters are applied to the subsequently-obtained measurement interferometric pattern data in order to distinguish between axial strain, bend strain, and twist strain on the fiber and to accurately determine one or more strain values for the fiber corresponding to one or more of the axial strain, bend strain, or twist strain on the fiber.
- a multi-core fiber coupling method includes a first alignment step, a first measurement step, a second alignment step, and a fusion step.
- first alignment step alignment is performed in a direction orthogonal to the major axis by relatively moving the multi-core fiber.
- first measurement step light is input to the first core of one multicore fiber, and the intensity of the light transmitted to the first core of the other multicore fiber is measured.
- second alignment step alignment in the rotation direction is performed by rotating the multi-core fiber relative to the rotation direction based on the intensity of the light measured in the first measurement step.
- the end face of one multicore fiber and the end face of the other multicore fiber are fused.
- Example embodiments of the technology described in this application relate to a method for using an optical frequency domain reflectometer (OFDR) system for aligning a sensing multicore optical fiber with an interrogating multicore optical fiber, and for carrying out distributed strain sensing.
- the sensing multicore optical fiber comprises an off-center sensing core paired with an off-center interrogating core in the interrogating multicore optical fiber to form an off-center core pair.
- the method comprises placing the sensing multicore optical fiber and the interrogating multicore optical fiber for abutment of connecting ends of the sensing multicore optical fiber and the interrogating multicore optical fiber.
- the OFDR system uses the OFDR system to interferometrically interrogate the off-center core pair through the off-center interrogating core and to determine a first reflection value from the off-center sensing core, wherein the first reflection value represents a degree of alignment for the off-center core pair in a first relative orientation between the connecting ends of the sensing multicore optical fiber and the interrogating multicore optical fiber.
- the OFDR system uses the OFDR system to interferometrically interrogate the off-center core pair through the off-center interrogating core and to determine a second reflection value from the off-center sensing core, wherein the second reflection value represents a degree of alignment for the off-center core pair in a second relative orientation between the connecting ends of the sensing multicore optical fiber and the interrogating multicore optical fiber.
- the method may be performed for multiple core pairs.
- the first reflection value that represents a degree of alignment for the off-center core pair in the first relative orientation is compared with the corresponding second reflection value that represents a degree of alignment for the off-center core pair in the second relative orientation, and the alignment orientation is identified based on the comparing.
- the adjusting may include rotation of one or both of the sensing core followed by interrogating core in the core pair.
- At least the ends of the sensing and interrogating multicore fibers are placed in a groove of a structure with the ends of the sensing and interrogating multicore fibers being brought into proximity for connection. One or both of the sensing and interrogating multicore fibers is then rotated in the groove.
- the sensing multicore fiber is included in a first ferrule and the interrogating multicore optical fiber is included in a second ferrule.
- the sensing multicore optical fiber and the interrogating multicore optical fiber are placed for abutment of the connecting ends.
- the adjusting the relative orientation between the connecting ends of the sensing multicore optical fiber and the interrogating multicore optical fiber comprises includes rotation of one or both of the first and second ferrules. At least the ends of the first and second ferrules may be placed in a split sleeve connector, and one or both of the first and second ferrules is/are rotated while the first and second ferrules are in the split sleeve.
- the sensing multicore optical fiber is associated with a surgical instrument an example application.
- the sensing multicore optical fiber comprises additional sensing cores paired with additional interrogating cores of the interrogating multicore optical fiber to form additional core pairs, wherein the OFDR system is further used to interrogate the additional core pairs through the interrogating cores and to measure reflected light from the additional sensing cores, wherein the reflected light from the additional sensing cores of the sensing multicore optical fiber is processed for distributed strain sensing, and wherein the distributed strain sensing in the off-center sensing core and the additional sensing cores is used to determine at least one of: a position and a shape of at least a portion of the instrument.
- the aligned orientation is based on a largest of the first and second reflection values, and wherein the off-center core pair in the alignment orientation produces a largest minimum measured reflection amplitude across all of the off-center core pair and the additional core pairs of the sensing multicore optical fiber and the interrogating multicore optical fiber.
- the alignment orientation may be identified based on one or more of insertion loss and return loss for the off-center core pair.
- the first and second reflection values may be from Bragg gratings in the off-center sensing core of the off-center core pair and/or from Rayleigh scatter in the off-center sensing core of the off-center core pair.
- Example embodiments of the technology described in this application also relate to an optical frequency domain reflectometry (OFDR) system for aligning a sensing multicore optical fiber with an interrogating multicore optical fiber and for carrying out distributed strain sensing, the sensing multicore optical fiber comprising an off-center sensing core paired with an off-center interrogating core in the interrogating multicore optical fiber to form an off-center core pair.
- OFDR optical frequency domain reflectometry
- the system comprisies an optical interferometric interrogator configured to interrogate the off-center core pair through the off-center interrogating core and to determine a first reflection value from the off-center sensing core, wherein the first reflection value represents a degree of alignment for the off-center core pair in a first relative orientation between connecting ends of the sensing multicore optical fiber and the interrogating multicore optical fiber.
- the optical interferometric interrogator is further configured to interrogate the off-center core pair through the off-center interrogating core and to determine a second reflection value from the off-center sensing core, wherein the second reflection value represents a degree of alignment for the off-center core pair in a second relative orientation between the connecting ends of the sensing multicore optical fiber and the interrogating multicore optical fiber.
- the system further comprises circuitry configured to identify an alignment orientation for the connecting ends of the sensing multicore optical fiber and the interrogating multicore optical fiber based on the first reflection value and the second reflection value.
- the system further comprises an actuator configured to adjust a relative orientation between the connecting ends of the sensing multicore optical fiber and the interrogating multicore optical fiber to the alignment orientation.
- the system further comprises a connector configured to connect the sensing multicore optical fiber to the interrogating multicore optical fiber in the alignment orientation.
- the optical interferometric interrogator is further configured to interrogate the off-center core pair through the off-center interrogating core and to measure reflected light from the off-center sensing core when the sensing multicore optical fiber and the interrogating multicore optical fiber are aligned and connected.
- the circuitry is further configured to process the reflected light from the off-center sensing core for distributed strain sensing.
- the circuitry may be configured to identify the alignment orientation based on the first reflection value and the second reflection value by: comparing the first reflection value that represents a degree of alignment in the first orientation with the second reflection value that represents a degree of alignment in the second orientation; and identifying the alignment orientation based on the comparison.
- the system includes a structure having a groove, and wherein the actuator is configured to rotate one or both of the sensing and interrogating multicore fibers while the sensing and interrogating multicore fibers are in the groove.
- the system includes a first ferrule including the sensing multicore fiber and a second ferrule including the interrogating multicore fiber.
- the actuator is configured to rotate one or both of the first and second ferrules.
- a split sleeve structure may be used to encompass at least the ends of the first and second ferrules configured to bring the ends of the sensing and interrogating multicore fibers into proximity for connection.
- the actuator is configured to rotate one or both of the first and second ferrules while the first and second ferrules are in the split sleeve.
- Example embodiments of the technology described in this application also relate to a surgical system wherein the sensing multicore optical fiber is associated with an instrument and comprises additional sensing cores paired with additional interrogating cores of the interrogating multicore optical fiber to form additional core pairs, wherein the optical interferometric interrogator is further configured to interrogate the additional core pairs through the interrogating cores and to measure reflected light from the additional sensing cores, and wherein the circuitry is further configured to process the reflected light from the additional sensing cores of the sensing multicore optical fiber for distributed strain sensing, and to use the distributed strain sensing in the off-center sensing core and the additional sensing cores to determine at least one of: a position and a shape of at least a portion of the instrument.
- the circuitry is configured to identify the alignment orientation based on a largest of the first and second reflection values, and wherein the off-center core pair in the alignment orientation produces a largest minimum measured reflection amplitude across all of the off-center core pair and the additional core pairs of the sensing multicore optical fiber and the interrogating multicore optical fiber.
- the circuitry is configured to identify the alignment orientation based on one or more of insertion loss and return loss for the off-center core pair.
- the first and second reflection values are from Bragg gratings in the off-center sensing core of the off-center core pair.
- diagrams herein can represent conceptual views of illustrative circuitry or other functional units.
- any flow charts, state transition diagrams, pseudocode, and the like represent various processes which may be substantially represented in computer-readable medium and so executed by a computer or processor, whether or not such computer or processor is explicitly shown.
- the functional blocks may include or encompass, without limitation, a digital signal processor (DSP) hardware, a reduced instruction set processor, hardware (e.g., digital or analog) circuitry including but not limited to application specific integrated circuit(s) (ASIC) and/or field programmable gate array(s) (FPGA(s)), and (where appropriate) state machines capable of performing such functions.
- DSP digital signal processor
- ASIC application specific integrated circuit
- FPGA field programmable gate array
- a computer is generally understood to comprise one or more processors or one or more controllers, and the terms computer, processor, and controller may be employed interchangeably.
- the functions may be provided by a single dedicated computer or processor or controller, by a single shared computer or processor or controller, or by a plurality of individual computers or processors or controllers, some of which may be shared or distributed.
- processor or “controller” also refers to other hardware capable of performing such functions and/or executing software, such as the example hardware recited above.
- two optical fibers may be connected such as but not limited to mechanical splicing that holds the ends of the fibers together mechanically and fusion splicing that uses heat to fuse the ends of the fibers together.
- the term connector encompasses the variety of ways for connecting optical fibers.
- Figures 1A and 1B show cross-sections of multicore optical fibers 10 and 12 to be connected, each fiber having four optical cores A, B, C, and D.
- the non-limiting example in the description uses four cores for illustration, the technology set forth in the application applies to two cores, three cores, and greater than four cores.
- the outer surfaces of the two multicore fibers 10 and 12 e.g., the ferrules covering the fibers, are aligned for connection, the corresponding cores A-A, B-B, C-C, and D-D within or at the connection for the two fibers may not be aligned or could be aligned more accurately.
- Figure 1B shows a clockwise rotational misalignment around the center core A such that cores B-B, C-C, and D-D for multicore fibers 10 and 12 are not aligned.
- Figure 2 shows an example structure 14 with a V-shaped groove in which the two fibers may be placed for abutment of the connecting ends of the fibers 10 and 12.
- the V-groove provides a fast, simple, and inexpensive structure for bringing two multicore fibers into abutment for connection and typically with the center cores A-A reasonably accurately aligned. But one or more off-center core pairs, B-B, C-C, and D-D in the examples in Figures 1A, 1B and 2A and 2B , are misaligned.
- the V-groove is an example of a groove. More generally, a groove encompasses a channel, a slot, a cut, a depression, and the like.
- Figures 3A and 3B show a breakaway of both sides of the V-groove supported fibers from Figure 2 indicating that rotation of at least one of the fibers is needed for better core alignment for the off-center core pairs.
- optical performance of the connected fiber decreases significantly, e.g., in term of insertion loss, return loss, etc.
- the groove alignment support is very low cost and advantageously provides a way to align and connect the cores in optical fibers placed into the groove without requiring the fibers to be encased in prealigned ferrules.
- a non-limiting ferrule and fiber alignment and connection example embodiment is described below in conjunction with Figure 10 .
- Figure 4 illustrates a non-limiting example that forms part of an embodiment of an interferometrically-based multicore fiber alignment system that overcomes these alignment problems and improves the optical performance of the connected fiber dramatically.
- This alignment system is particularly advantageous when an optical interrogator is connected to the optical fiber in normal use. In other words, since the optical interrogator is already present, using it to provide information about the quality of the core alignment and/or connection does not add expense or significant complexity to the system.
- Figure 4 is described in conjunction with the flowchart in Figure 5 illustrating example procedures for interferometrically-based multicore fiber alignment.
- the ends of the sensing and interrogating optical multicore fibers 10 and 12 are placed in a groove of structure 14 into proximity for connection in a first orientation with cores in the sensing multicore fiber being paired up with corresponding cores in a second multicore fiber, e.g., cores A-A are a core pair and cores B-B are a core pair (step S1).
- the sensing fiber 10 in this example is on a sensor or application side of the connection
- the interrogating fiber 12 in this example is on an optical interrogator side of the connection.
- An optical interferometer (an interferometric interrogation system 18 in the example embodiment of Figure 4 ) interrogates one or more pairs of cores and determines a first value that represents a first degree of alignment for one of the one or more pairs of cores in the first orientation (step S2). Although multiple or even all of the pairs of cores may be interrogated and processed, satisfactory results may be obtained by interrogating just one radial core pair (other than the center core pair).
- the relative position between the ends of two multicore fibers is adjusted to a second orientation via an actuator (step S3).
- the actuator is a fiber rotator 22 controlled by a controller 20, which receives an output signal from the interferometric interrogation system 18.
- a fiber rotator be used on the sensor side, or two fiber rotators could be used.
- the fiber rotator may be controlled by a signal directly from the interferometric interrogation system 18.
- the optical interferometer subsequently interrogates the one or more pairs of cores and determines a second reflection value from the sensing multicore optical fiber in the one pair of cores that represents a degree of alignment for the one pair of cores in the second orientation (step S4).
- the first reflection value that represents a degree of alignment for the one pair of cores in the first orientation are compared by a comparator with the corresponding second reflection value that represents a degree of alignment for the one pair of cores in the second orientation (step S5).
- the comparator could be a part of other circuitry, part of the interferometric interrogation system 18, part of the controller 20, or even a standalone circuit.
- An alignment orientation for connecting the two multicore fibers may then be determined based on the comparison (step S6).
- the orientation with the greatest reflection value may be used.
- the process may repeat one or more times starting from step S3 until an orientation with a greatest reflection value is determined.
- the process may repeat one or more times starting from step S3 until a predetermined level of alignment accuracy is achieved.
- the fibers are connected at the orientation with the desired alignment.
- the optical interrogator assesses the quality of the orientation and/or connection between the outer cores of the connected multicore fiber.
- the interrogator may sense Bragg grating signal amplitude or Rayleigh scattering amplitude from interrogated core pairs depending on the type of sensor.
- the interrogator continuously measures the amplitude of the measured light signal as the connection for one or more core pairs is adjusted. The connection adjustment that produces a largest minimum amplitude across all of the cores may be used for example because tests have shown that performance is often controlled by the lowest performing core pair in a multicore fiber.
- FIG. 6 shows a non-limiting example embodiment using an Optical Frequency Domain Reflectometry (OFDR)-based multicore fiber alignment system that finds advantageous example application to optical strain sensing.
- Optical strain sensing is useful for measuring physical deformation of a core caused by, for example, the change in tension, compression, or temperature of an optical fiber.
- a continuous measure of strain along the length of a core can be derived by interpreting the optical response of the core using swept wavelength inteferometery.
- Optical time domain measurements with high resolution and high sensitivity may be achieved using Optical Frequency Domain Reflectometry (OFDR). These measurements enable several important fiber-optic sensing technologies, such as distributed strain sensing.
- OFDR Optical Frequency Domain Reflectometry
- a multiple channel OFDR is connected to several independent optical cores within the multi-core optical fiber.
- the strain responses of these cores are simultaneously measured as the fiber is placed in a given configuration.
- the relative positions of the cores along the length of the multi-core optical fiber allow determination of a strain profile of the multi-core optical fiber.
- the strain profile may be used to determine the three dimensional position of the fiber, or one or more of the components (1)-(3) of this profile may be used independently.
- An OFDR-based distributed strain sensing system includes a tunable light source 23, an interferometric interrogator 26, a laser monitor network 28, an optical fiber sensor including an interrogator side fiber 12, a connector 24, and a sensor side fiber 10, data acquisition electronic circuitry 32, and a system controller data processor 30 as depicted in an example multichannel OFDR system 21 in Figure 6 . Each channel corresponds to a fiber core.
- Figure 7 is a flowchart illustrating example procedures for interferometrically-based multicore fiber alignment and connection for interferometrically-based multicore fiber alignment and connection system in Figure 6 .
- the steps describe the operation for one core that is applied to each of the cores in the multicore fiber.
- a tunable light source 23 is swept through a range of optical frequencies (step S10). This light is split with the use of optical couplers and routed to two separate interferometers: those of interferometric interrogator 26 and laser monitor network 28.
- the first interferometer 26 serves as an interferometric interrogator (and may be called interferometric interrogator 26) and is connected via a connector 24 to a length of multicore sensing fiber.
- Light enters the multicore sensing fiber 10 through the measurement arm of the interferometric interrogator 26 (step S11). Scattered light from the sensing fiber 10 is then interfered with light that has traveled along the reference arm of the interferometric interrogator 26 (step S12).
- the laser monitor network 28 contains a Hydrogen Cyanide (HCN) gas cell that provides an absolute wavelength reference throughout the measurement scan (step S 13).
- HCN Hydrogen Cyanide
- the second interferometer, within the laser monitor network 28, is used to measure fluctuations in tuning rate as the light source is scanned through a frequency range (step S14).
- a series of optical detectors e.g., photodiodes
- convert the light signals from the laser monitor network, gas cell, and the interference pattern from the sensing fiber to electrical signals step S15.
- a data processor in a data acquisition unit 32 uses the information from the interferometer of the laser monitor network 28 to resample the detected interference pattern of the sensing fiber 10 so that the pattern possesses increments constant in optical frequency (step S16).
- This step is a mathematical requisite of the Fourier transform operation.
- a Fourier transform is performed by the system controller 30 to produce a light scatter signal in the temporal domain for an initial orientation of the multicore fibers 12 or 10 (step S17).
- the amplitudes of the light scattering events are depicted verses delay along the length of the fiber. Using the distance that light travels in a given increment of time, this delay can be converted to a measure of length along the sensing fiber.
- the light scatter signal indicates each scattering event as a function of distance along the fiber.
- the sampling period is referred to as the spatial resolution and is inversely proportional to the frequency range that the tunable light source 23 was swept through during the measurement.
- One or both of the multicore fibers 12 or 10 is adjusted to a new orientation, e.g., rotated by fiber rotator 22 or by a ferrule rotator such as that shown below in Figure 10 , and then the steps S10-S17 are repeated (step S18).
- the scatter amplitudes for the initial orientation are compared to those for the new orientation (or the amplitudes for the two most recent orientations are compared) to determine if they are within an acceptable difference (step S19). If not, then the process returns to step S18; if so, then the adjustment is complete (step S20), and the fibers are connected.
- Figure 8 shows a non-limiting example embodiment for a surgical system 800 that includes a manipulator arm 810 on which a surgical instrument 850 is removably mounted via a mounting interface 816.
- Mounting interface 816 allows communication between surgical system 800 and instrument 850 of power, data, control signals, and any other operative modalities.
- a local or remote user interface 802 allows a user to interact with surgical system 800 and instrument 850.
- Surgical system 850 further includes a multiple channel OFDR system 21 coupled to an interrogating fiber 12 that terminates in a connector 812.
- Instrument 850 includes a sensing fiber 10 that terminates in a connector 852 that mates with connector 812.
- Surgical system 850 also includes an alignment actuator 814 that allows rotation of fiber 12 in response to measurements by multiple channel OFDR system 21 to align the interrogator side and sensor side fibers for connector 24, as explained in example embodiments above (in various embodiments, multiple channel OFDR system 21 can also be used to measure the shape of and/or strain associated with surgical instrument 850 during clinical use).
- alignment actuator 814 can be an active adjustment mechanism (e.g., a motorized system that adjusts the rotation of interrogating fiber 12 with respect to sensing fiber 10 in response to the output of multiple channel OFDR system 21), and in other embodiments, alignment actuator 814 can be a passive adjustment mechanism (e.g., a manually adjustable structure that a user manipulates in response to the output of multiple channel OFDR system 21). In various other embodiments, alignment actuator 814 can include both automated and manual adjustment capabilities.
- active adjustment mechanism e.g., a motorized system that adjusts the rotation of interrogating fiber 12 with respect to sensing fiber 10 in response to the output of multiple channel OFDR system 21
- alignment actuator 814 can be a passive adjustment mechanism (e.g., a manually adjustable structure that a user manipulates in response to the output of multiple channel OFDR system 21).
- alignment actuator 814 can include both automated and manual adjustment capabilities.
- alignment actuator 814 is depicted on manipulator arm 810 for exemplary purposes, in various other embodiments, alignment actuator 814 can be positioned anywhere on surgical system 800.
- instrument 850 can additionally or alternatively include its own alignment actuator 854 (active and/or passive) for adjusting the rotation of sensing fiber 10 with respect to interrogating fiber 12.
- alignment actuator 854 active and/or passive
- FIG. 8 the particular routing and placement of sensing fiber 10 and interrogating fiber 12 depicted in FIG. 8 is intended to be exemplary and not limiting.
- fiber 12 can be routed on or within manipulator arm 810 or along any other path.
- Figure 9A shows a non-limiting example embodiment involving a multicore fiber in a ferrule.
- Figures 9B and 9C show a side view of an exaggerated example of cleaved ends of abutting misaligned multicore fibers 10 and 12 to be connected in their respective ferrules 13 and 15.
- Ferrule mounted fibers are often angle polished to reduce reflection with ferrule and fiber end angles other than 90 degrees, e.g., 8 or 9 degrees from vertical. Alignment of ferrule mounted fibers is also a problem, even in the presence of the angle polish.
- Figure 10 shows non-limiting details for an example connector for connecting two multicore fibers embedded in their respective ferrules for alignment in accordance with another example embodiment.
- Figures 3A and 3B above show a groove to initially align the center cores of two optical fibers for connection without ferrules.
- Figure 10 uses a split sleeve connector because commercially available and inexpensive sapphire ferrules and split sleeve connectors do a good job of aligning the center cores of multicore fibers that have center cores when the two ferrules are abutted together. This relatively cheap and easy split sleeve connector restricts the active alignment to a single degree of freedom of the connector.
- a round ferrule 37 holds the interrogator side multicore fiber 10 precisely (e.g., +- ⁇ 1 micron) in the center of a high precision, preferably but not necessarily mass-produced split sleeve 36.
- the split sleeve is flexibly supported, e.g., by springs 38, so that it can adjust position.
- the ferrule 37 for the multicore fiber 10 is solidly connected to a structure 40 with a relatively large flat surface to fix the rotational angle of the ferrule.
- the rotatable ferrule 39 contains the sensor side multicore fiber 12. Flexibly mounting the split-sleeve 36 allows the split-sleeve 36 to reposition in space to accommodate the two ferrules 39 and 37.
- the ferrule 39 is rotated using a multi-link universal joint 42 connected to a motor 44 that transmits torque and some axial force. Although there is a space shown between the ferrules 39 and 37, in practice they are moved into contact, e.g., by springs that provide a compressional force on the sensor side. Once optimal core alignment is achieved, the two fibers may be connected.
- Figures 11A-11E are example graphs of reflection v. distance showing iterative increasing alignment of two multicore fibers using the example OFDR-based multicore fiber alignment system. If the cores are not well aligned, and reflection is measured as a function of distance along the center core and one outer core, the plot shown in Figure 11A is produced with the substantial amplitude difference shown. The dark waveform corresponds to the reflected amplitude detected for the center core and the lighter waveform corresponds to the reflected amplitude detected for one outer core. As the two multicore fibers are rotated towards closer alignment, the amplitude on the outer core (lighter waveform) gets progressively larger as shown in Figures 11B-11D . Figure 11E signals that a desired alignment is achieved, e.g., when the two waveforms have about the same average amplitude.
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PCT/US2016/024021 WO2016160513A1 (en) | 2015-03-27 | 2016-03-24 | Interferometric alignment of optical multicore fibers to be connected |
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EP (1) | EP3274750B1 (ko) |
JP (1) | JP6799535B2 (ko) |
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US20180172920A1 (en) | 2018-06-21 |
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EP3274750A1 (en) | 2018-01-31 |
KR102579618B1 (ko) | 2023-09-18 |
CN107111078A (zh) | 2017-08-29 |
WO2016160513A1 (en) | 2016-10-06 |
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US10416391B2 (en) | 2019-09-17 |
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